Special effect image generating apparatus

ABSTRACT

A special effect image generating apparatus provided with an image conversion processing circuit for posterization or other image conversion, a luminance and chroma condition setting circuit for image extraction by luminance and colors, a mask pattern generator for selection of a mask, and mixer for preparing a video signal, a transformation unit for transformation processing such as movement, and a post video modification unit for addition of a locus etc. The extracted image automatically tracks movement of the image so there is no change in visual effects, images having the same luminance and color conditions can be deleted by mask adjustment, movement of the image can be handled by adjustment of the mask, and highly accurate boundaries can be set by the wave-filtering and shaping circuit. Therefore, a special effect image with distinctive luminance and color can be easily prepared.

This is a continuation of application Ser. No. 09/842,933 filed Apr. 26,2001 now U. S. Pat. No. 7,015,977, the entirety of which is incorporatedherein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a special effect image generatingapparatus for processing an image to generate a special effect.

2. Description of the Related Art

Processing original data for an image to give it a unique visual effectis a common practice in preparing television broadcast images andvarious other various. The types of image processing include“posterization” and “solarization” for reducing the number of gradientsof the image data, “mosaic” processing for dividing an image to blocksof uniform densities, “mono” processing for making an image monochrome,“contrast” processing for adjusting the luminance difference of animage, and other various types of processing.

The special effect image generating apparatus of the related artperforms the above variety of processing on an image as selected in animage conversion processing circuit. When doing this, it generates amask pattern from a mask pattern generator to mask regions of the imagenot to be processed and used this mask pattern so as to process onlypredetermined regions of the image.

In the above special effect image generating apparatus of the relatedart, since predetermined positions of the image input to the apparatuswere masked regardless of the state of the input image, when for exampleperforming mosaic processing, the operator had to control the maskconditions to deal with any movement of the portions of the image to bemasked accompanying movement of the input image. This adjustingoperation required a lot of work.

SUMMARY OF THE INVENTION

An object of the present invention is to provide a special effect imagegenerating apparatus capable of processing an input image based onluminance information and color information with a high accuracy whilesuitably handling even movement of the image and without imposing anyburden on an operator in an adjusting operation so as to generate aspecial effect giving visually unique luminance and color effects.

To attain the above object, according to the present invention, there isprovided a special effect image generation apparatus for processing animage to generate a special effect, comprising an image conversion meansfor performing predetermined image conversion on the image; anextraction condition setting means for extracting from the above imagean image satisfying a plurality of extraction conditions among luminanceextraction conditions based on a luminance signal and/or chromaextraction conditions based on at least a color signal; a key signaloutput means for outputting a key signal for setting extractionconditions for the image based on the luminance extraction conditionsand/or the chroma extraction conditions; and a mixer circuit forprocessing the image to convert the image to a special effect imagebased on a signal of the image, an output signal of the image conversionmeans, and the key signal.

Preferably, the special effect image generation apparatus furthercomprises a mask pattern generation means for outputting a mask patternfor masking a region not to be processed in the image, and the keysignal output means outputs a key signal to set the extractionconditions for the image based on the mask pattern in addition to theluminance extraction conditions and/or chroma extraction conditions.

Alternately, the special effect image generation apparatus furthercomprises an image conversion setting and processing means for selectingand setting a type of image conversion to be performed on the image andmaking the image conversion means perform the selected and set imageconversion on the image; and the selection and setting of the type ofimage conversion in the image conversion setting and processing meansand the setting of the luminance extraction conditions and/or chromaextraction conditions are freely and independently performed.

More preferably, the special effect image generation apparatus furthercomprises a mask pattern generation means for outputting a mask patternto mask a region not to be processed in the image; the key signal outputmeans outputs a key signal for setting the extraction conditions for theimage based on the mask pattern in addition to the luminance extractionconditions and/or chroma extraction conditions; and the setting andadjustment of the mask pattern generated by the mask pattern generationmeans, the selection and setting of the type of image conversion in theimage conversion setting and processing means, and the setting of theluminance extraction conditions and/or chroma extraction conditions arefreely and independently performed.

Alternatively, the special effect image generation apparatus furthercomprises a wave-filtering and shaping means for filtering and shapingthe output signal of the extraction condition setting means.

Preferably, the image conversion means reduces the number of gradientsof data of the image.

Alternatively, the image conversion means divides the image into blocksof uniform density.

Preferably, the chroma extraction conditions are extraction conditionsbased on a luminance signal and color difference signal of the image.

Alternatively, the chroma extraction conditions are decided for atwo-dimensional region of a color difference value defined by a colordifference signal of blue and luminance and a color difference signal ofred and luminance of the image.

More preferably, the chroma extraction conditions are decided for athree-dimensional region of a color difference value and a luminancevalue defined by a color difference of a two-dimensional region of thecolor difference signal and a luminance value at a predeterminedposition in the two-dimensional region.

Preferably, the extraction condition setting means extracts an imagebased on an NAM output of the luminance extraction conditions and/or thechroma extraction conditions.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other objects and features of the present invention willbecome clearer from the following description of the preferredembodiments given with reference to the attached drawings, in which:

FIG. 1 is a block diagram of the configuration of a key portion of anembodiment of the present invention;

FIG. 2 is a block diagram of the overall configuration of an embodimentof the present invention;

FIGS. 3A to 3D are views for explaining preparation of a key signalcorresponding to the luminance of an input image of an embodiment of thepresent invention;

FIGS. 4A and 4B are views for explaining preparation of a key signalcorresponding to regions having a reference luminance or more or areference luminance or less in the input image of an embodiment of thepresent invention;

FIGS. 5A to 5C are views for explaining preparation of a key signalcorresponding to a predetermined range of a luminance region of theinput image of an embodiment of the present invention; and

FIGS. 6A and 6B are views for explaining preparation of a key signalcorresponding to a color signal of an input image of an embodiment ofthe present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Below, preferred embodiments of the present invention will be explainedwith reference to FIGS. 1 to 6.

FIG. 1 is a block diagram of the configuration of a key portion of thepresent embodiment, FIG. 2 is a block diagram of the overallconfiguration of the present embodiment, FIGS. 3A to 3D are views forexplaining preparation of a key signal corresponding to luminance of aninput image of the present embodiment, FIGS. 4A and 4B are views forexplaining preparation of a key signal corresponding to regions having areference luminance or more or a reference luminance or less in theinput image of the present embodiment, FIGS. 5A to 5C are views forexplaining preparation of a key signal corresponding to a predeterminedrange of a luminance region of the input image of the presentembodiment, and FIGS. 6A and 6B are views for explaining preparation ofa key signal corresponding to a color signal of an input image of thepresent embodiment.

In the present embodiment, as shown in FIG. 2, a control panel 20 isprovided to enable an operator to input a variety of operation signals,a system CPU 21 for controlling the overall operation is connected tothe control panel 20, and a pre video modification unit 23 is connectedto the system CPU 21. The pre video modification unit 23 comprises, asshown in FIG. 1, an image conversion processing circuit 1 for performing“posterization” for reducing the number of gradients of luminance dataof an image, “solarization” for reducing the number of gradients oncolor data of the image, “mono” processing for making the imagemonochrome, “contrast” processing for adjusting luminance differences ofthe image, etc., a luminance and chroma condition setting circuit 7 forextracting an image satisfying luminance extraction conditions set inthe image and chroma extraction conditions, and a mask pattern generator14 for outputting a mask pattern for masking a region not to beprocessed in the image.

Also, the system CPU 21 is connected to an address generator 22 whichoutputs a corresponding address at the time of enlargement and/orreduction, movement, and page turning of the image. The addressgenerator 22 is connected to a transformation unit 24 for performing theabove enlargement and/or reduction. An input terminal of thetransformation unit 24 is connected to an output terminal of the abovepre video modification unit 23. Furthermore, the transformation unit 24is provided with a mapping memory used in the enlargement and/orreduction and an anti-alias filter for removing jags generated atoblique lines in the image along with the enlargement and/or reduction.

Similarly, the system CPU 21 is connected to a post video modificationunit 25. An input terminal of the post modification unit 25 is connectedto an output terminal of the above transformation unit 24. The postvideo modification unit 25 has the functions of adding to an outputsignal of the transformation unit 24 a tail shaped moving locus or astar shaped moving locus at the time of moving an image and adding abackground to an image according to a selecting operation by theoperator.

The key portion of the pre video modification unit 32 of the presentembodiment is configured as shown in FIG. 1 and comprises an imageconversion processing circuit 1 for performing “posterization” forreducing the number of gradients on luminance data of an image,“solarization” for reducing the number of gradients on color data of theimage, “mosaic” processing for dividing an image to blocks of uniformdensity, “mono” processing for making the image monochrome, “contrast”processing for adjusting luminance differences of the image, etc., adelay circuit 3 for delaying an input image signal, and a key signalgenerator 15 for outputting a key signal for processing the input imageconnected in parallel to an input terminal “ti”. An output terminal ofthe image conversion processing circuit 1 is connected to the delaycircuit 2, an output terminal of the delay circuit 2 is connected to afirst input terminal of a mixer circuit 5, an output terminal of thedelay circuit 3 is connected to a second input terminal of the mixercircuit 5, and an output terminal of the key signal generator 15 isconnected to a third input terminal of the mixer circuit 5 via a switch13 and a delay circuit 6. The mixer circuit 5 has a function ofpreparing a special effect image and outputting a corresponding specialeffect image signal based on an output signal of the delay circuit 2, anoutput signal of the delay circuit 3, and an output signal of the delaycircuit 6.

The above key signal generator 15 is provided with a luminance andchroma condition setting circuit 7 for extracting and outputting animage portion corresponding to luminance and chroma conditions set bythe operator based on the luminance and colors of the image from theinput image. The input terminal ti of the image signal is connected toan input terminal of the luminance and chroma condition setting circuit7. The luminance and chroma condition setting circuit 7 comprises aplurality of lumi-key setting circuits 16 a to 16 m set with extractionluminance conditions based on the luminance of the image and a pluralityof chroma key setting circuits 18 a to 18 n set with extraction chromaconditions based on the luminance and colors connected in parallel tothe input terminal “ti”. The lumi-key setting circuits 16 a to 16 m arerespectively connected to inversion circuits 17 a to 17 m, while thechroma key setting circuits 18 a to 18 n are respectively connected toinversion circuits 19 a to 19 n. When the levels of the input signalsoverlap, the output terminals of the inversion circuits 17 a to 17 m and19 a to 19 n are connected to a NAM circuit 9 for selecting a signal ofthe higher level and outputting the same. An output terminal 9 of theNAM circuit 9 becomes an output terminal of the luminance and chromacondition setting circuit 7.

In the key signal generator 15, the output terminal of the luminance andchroma condition setting circuit 7 is connected to a wave-filtering andshaping circuit 8 for two-dimensional low pass filtering and signalshaping. The output terminal of the wave-filtering and shaping circuit 8is connected to the inversion circuit 10 via a switch 11. Furthermore,an output terminal of the inversion circuit 10 is connected to a maskprocessing circuit 12, while the mask processing circuit 12 is connectedto a mask pattern generator 14 for outputting a desired mask patternsignal by operation by the operator. The mask processing circuit 12 hasa function of masking an output signal from the luminance and chromacondition setting circuit 7 to be processed in the wave-filtering andshaping circuit 8 by a mask pattern signal from the mask patterngenerator 14. An output terminal of the mask processing circuit 12 isconnected to a delay circuit 6 via a switch 13, while an output terminalof the delay circuit 6 is connected to the third input terminal of themixer circuit 5.

The operation of the present embodiment configured in this way will beexplained next. The operator inputs from the control panel 20 theinstruction operation signal necessary for the processing of the image.The instruction operation signal includes an image conversioninstruction for selecting image conversion processing of “posterization”for reducing the number of gradients in luminance data of an image ofthe image conversion processing circuit 1 of the pre video modificationunit 23, “solarization” for reducing the number of gradients in colordata of the image, “mosaic” processing for dividing an image into blocksof uniformed density, “mono” processing for making the image monochrome,“contrast” processing for adjusting luminance differences of the image,etc. Further, the instruction operation signal includes a luminance andchroma condition instruction of the luminance and chroma conditionsetting circuit 7 and a mask instruction for instructing a shape andposition of a mask pattern to be generated by the mask pattern generator14. Furthermore, the instruction operation signal input from the controlpanel 20 includes, if required, an image transformation instruction forenlarging, reducing, moving, and rotating a designated portion of animage by selection by the operator.

Here, the luminance and chroma condition instruction of the luminanceand chroma condition setting circuit 7 entered by the operator will beexplained. First, the setting of a lumi-key for deciding the extractionluminance conditions based on the luminance of the image will beexplained. The extraction luminance conditions are set based on theluminance of the image in this case by the operator operating a levelsetting device provided on the control panel 20 and having a displaypanel displaying a luminance range (0 to 10) of the image.

FIG. 3A is a view of the relationship between a luminance level L of theinput image signal of the image and time “t”, wherein a key signal Fk3shown in FIG. 3D is output as a key signal for extracting from the inputimage signal an image having a luminance level of a predetermined levelL4 or more set in advance. In this case, as shown in FIG. 4A, an outputlevel signal “Out” is found by multiplying an amplification constant“gain” with a difference of a luminance level signal “in” of the inputimage and an upper limit reference value “clip”. A key signal Fk3 asshown in FIG. 3D can be obtained by a limiter circuit making the outputlevel signal “Out” zero when “Out”<0 and making “Out” 1.0 when“Out”>1.0.

Also, a key signal Fk1 shown in FIG. 3B is output as a key signal forextracting from the input image signal an image having a luminance levelof a predetermined level L1 or less set in advance. In this case, asshown in FIG. 4B, an output level signal “Out” is found by multiplyingan amplification constant “gain” with a difference of a luminance levelsignal “in” of the input image and a lower limit reference value “min”.A key signal Fk1 as shown in FIG. 3B can be obtained by a limitercircuit making the output level signal “Out” 0 when “Out”<0 and making“Out” 1.0 when “Out”>1.0.

As a key signal for extracting from the input image signal an image of aluminance level of a predetermined level range (L2<L<L3) set in advance,a key signal Fk2 shown in FIG. 3C is output. In this case, a centralvalue “center” of the upper limit value L3 (clip) and the lower limitvalue L2 (min) is obtained as shown in FIG. 5A. An absolute value “ABS”of the difference of the luminance level signal “in” of the input imageand “center” is calculated as shown in FIG. 5B. Furthermore, as shown inFIG. 5C, the absolute value “ABS” of the difference of the luminancelevel signal “in” of the input image and “center” is subtracted from the“clip”, and the output level signal “Out” is calculated by multiplyingthe subtracted value with the amplification constant “gain”. A keysignal Fk2 as shown in FIG. 3C can be obtained by the limiter circuitwhich makes the output level signal “Out” 0 when “Out”<0 and makes “Out”1.0 when “Out”>1.0.

Next, the setting of a chroma key for deciding the extraction chromaconditions based on colors or both luminance and colors of the imagewill be explained. When the control panel 20 is provided with atwo-dimensional chroma key setting device for two-dimensionally settinga color signal region of an extracted signal on a two-axis planecomprised of a U-axis of the chromaticity signal (B-Y) and a V-axis ofthe chromaticity signal (R-Y) by an input of boundary angles from areference chromaticity signal axis, the chroma key for deciding theextraction chroma conditions based on the colors or both luminance andcolors of the image is set by an operator operating the two-dimensionalchroma key setting device. When the control panel 20 is provided with athree-dimensional chroma key setting device for three-dimensionallysetting a color signal region of the extracted signal on a two-axisplane comprised of a U-axis of the chromaticity signal (B-Y) and aV-axis of the chromaticity signal (R-Y) by an input of boundary anglesfrom a reference chromaticity signal axis and furthermore the luminanceY of the color signal is also in accordance with a set distance from thereference position, the key is set by an operator operating thethree-dimensional chroma key setting device.

When setting a color signal region of the extracted image from thetwo-dimensional chroma key setting device, by entering boundary anglesθ1 and θ2 to the two-dimensional chroma key setting device, a boundaryangle signal from the U-axis of the chromaticity signal (B-Y) is inputon the two-axis plane comprised of the U-axis of the chromaticity signal(B-Y) and the V-axis of the chromaticity signal (R-Y) as shown in FIG.6A and a color signal region 26 of the extracted image is selectedtwo-dimensionally as shown in the shaded portion in FIG. 6A. The logicvalue of the chroma key signal becomes “1” in the color signal region26, while becomes “0” in other regions. Also, when setting a colorsignal region of the extracted image from the three-dimensional chromakey setting device, by entering boundary angles in the same way as inthe two-dimensional chroma key setting device and furthermore inputtingthe luminance Y of a color signal in accordance with the set distancefrom the reference position, a color signal region 27 of, for example, asphere having a radius of “r” from a central point “P”, is selected onthe three-dimensional coordinates including the luminance Y as shown inFIG. 6B. The logic value of the chroma key signal becomes “1” in thecolor signal region 27 and becomes “0” in regions other than that.

Similarly, lumi-key signals output from the plurality of lumi-keysetting circuits 16 a to 16 m set with extraction luminance conditionsbased on the luminance of the image and chroma key signals output fromthe plurality of chroma key setting circuits 18 a to 18 n set withextraction chroma conditions based on colors or both luminance andcolors of the image are respectively input to the NAM circuit 9 via theinversion circuits 17 a to 17 m and 19 a to 19 n. When extractionconditions overlapping with the input signals are set by the NAM circuit9, the one having the higher level is selected and output. An outputsignal of the luminance and chroma condition setting circuit 7 is inputto the wave-filtering and shaping circuit 8 for two-dimensional low passfiltering and signal shaping, and then input to the mask processingcircuit 12 via the switch 11, which is normally switched to the terminal“t3” side when used. The mask processing circuit 12 is receives by inputby the operator a mask pattern signal from the mask pattern generator 14for outputting a desired mask pattern signal. When the mask patternsignal is input, the output signal of the luminance and chroma conditionsetting circuit 7 processed in the wave-filtering and shaping circuit 8is masked by the mask pattern signal. An output signal from the maskprocessing circuit 12 is input to the delay circuit 6 via the switch 13,which is normally switched to the terminal “t1” side when used.

On the other hand, for example, when image conversion processing of“posterization” for reducing the number of gradients of luminance dataof the image and “solarization” for reducing the number of gradients ofcolor data of the image are selected in the image conversion processingcircuit 1 of the pre video modification unit 23 by an image conversioninstruction in the instruction operation signal input from the controlpanel 20 by the operator, an image signal obtained by “posterization”and “solarization” of an input image signal from the input terminal “ti”is input to the delay circuit 2. At the same time, the input imagesignal from the input terminal “ti” is input to the delay circuit 3.Then, a delay of the output signal of the mask processing circuit 12 isadjusted in the delay circuit 6, a delay of the output signal of theimage conversion processing circuit 1 is adjusted in the delay circuit2, and a delay of the input image signal is adjusted in the delaycircuit 3. In the state where phases of the above match, the outputsignal of the image conversion processing circuit 1 is input to thefirst input terminal of the mixer circuit 5, the input image signal isinput to the second terminal of the mixer circuit 5, and the outputsignal of the mask processing signal 12 is input to the third inputterminal of the mixer circuit 5.

The mixer circuit 5 designates a key signal output from the key signalgenerator 15 as “K”, multiplies “K” with a difference signal of aconversion image signal “A” obtained by image conversion of the inputimage signal of the input terminal “ti” in the image conversionprocessing circuit 1 and an image signal “B” which is the input imagesignal after passing through the delay circuit 3. Then, the image signal“B” is added to the calculated value. As a result, the mixer circuit 5outputs a video signal “Out” ((A−B)·K+B). As shown in FIG. 2, the videosignal is input to the transformation unit 24 from the pre videomodification unit 23, however, when an image conversion instruction forreducing and moving a designated portion in the image to be processed isincluded in the instruction operation signal input from the controlpanel by the operator, an address signal for reduction and movement issupplied to the transformation unit 24 from the address generator 22 byan instruction signal from the system CPU 21. The transformation unit 24performs processing for reduction and movement of the designated portionin the image. When jags etc. are generated at oblique line portions inthe image, the jags are removed by the anti-alias filter. The processedimage signal is then input to the post video modification unit 25.

In this case, when addition of a tail shaped moving locus or a starshaped moving locus or addition of background at the time of moving animage is selected for the output signal of the transformation unit 24 bya selecting operation by the operator, a tail shaped moving locus or astar shaped moving locus or a background is added in the post videomodification unit 25. The special effect image finally obtained by theimage processing is output from the post video modification unit 25.

As explained above, according to the present embodiment, imageconversion processing of “posterization” and “solarization” for reducingthe number of gradients of the image data, “mosaic” processing fordividing the image to blocks of uniform density, “mono” processing formaking the image monochrome, or “contrast” processing for adjusting theluminance differences of the image is selected in the image conversionprocessing circuit 1 by a selection operation by the operator.Extraction luminance conditions based on the luminance of the image andextraction chroma conditions based on the colors or both luminance andcolors of the image are set. A shape and position of the mask patterngenerated from the mask pattern generator 14 are selected in theluminance and chroma condition setting circuit 7. Then, the mixercircuit 5 processes a selected part of the image.

For a video signal, the transformation unit 24 performs variousprocessing such as reduction and movement and removes the jags generatedalong with the processing. The post video modification unit 25 adds atail shaped moving locus or a star shaped moving locus or adds abackground to the image in accordance with need. Therefore, it ispossible to give a visually unique effect in terms of luminance andcolors to an image by an easy operation. Also, according to the presentembodiment, even if the image moves, the image portion extracted by theset luminance and chroma conditions automatically moves in accordancewith the movement of the image. Therefore, it is possible to preventchanges generated in the visual effects of the special effect image.Furthermore, it is possible to process only part of a plurality of imageparts having the same luminance and chroma conditions, for example, onlyone of two face images on a display screen, by easily adjusting the maskpattern from the mask pattern generator 14 to obtain a mask having aminimum area extending over a wide range.

Furthermore, it is possible to swiftly track movement and changes of themask portion caused by movement of the image over a wide area with ahigh accuracy. Further, since the boundary region of the output signalfrom the luminance and chroma condition setting circuit 7 is broadenedby the wave-filtering and shaping circuit 8 and the mask pattern fromthe mask pattern generator 14 is adjusted at a high accuracy, a portiondesired to be processed can be completely covered when processing. Forexample, by broadening the boundary, it is possible to preventincomplete mosaic processing, for example, leaving part of the face asit is when trying to give a mosaic effect to completely cover the face.By keeping the area of the mask portion to a minimum, it becomespossible to easily prepare a special effect image giving a clear andvisually impressive effect excelling in luminance and color to arequired region.

As explained above, the special effect image generation apparatus of thepresent embodiment comprises an image conversion means for performingpredetermined image conversion on the image; an extraction conditionsetting means for extracting from the above image an image satisfying aplurality of extraction conditions among luminance extraction conditionsbased on a luminance signal and/or chroma extraction conditions based onat least a color signal; a key signal output means for outputting a keysignal for setting extraction conditions for the image based on theluminance extraction conditions and/or the chroma extraction conditions;and a mixer circuit for processing the image to convert the image to aspecial effect image based on a signal of the image, an output signal ofthe image conversion means, and the key signal.

More specifically, it further comprises a mask pattern generation meansfor outputting a mask pattern for masking a region not to be processedin the image and an image conversion setting and processing means forselecting and setting a type of image conversion to be performed on theimage and making the image conversion means perform the selected and setimage conversion on the image.

According to the above embodiment, the image conversion setting andprocessing means selects and sets a type of image conversion to beperformed on the image and performs the image conversion to the selectedand set image, the extraction condition setting means sets luminanceextraction conditions based on a luminance signal and chroma extractionconditions based on the luminance signal and color signals for theimage, the region not to be processed in the image is masked by the maskpattern output from the mask pattern generation means, and a key signalof a portion to be extracted in the image which satisfies thepredetermined luminance and chroma extraction conditions is output.Then, based the image signal, the output signal of the image conversionand setting processing means, and the key signal, the mixer circuitprocesses the image for the selected image conversion and extraction ofimage parts based on the predetermined luminance and chroma extractionconditions. Due to this, a predetermined image part in the image isextracted by distinctive luminance and chroma conditions and isconverted to a special effect image.

As a result, it is possible to give a special effect to a predeterminedpart in an image and easily generate a high quality special effect imagehaving a distinctive visual effect in luminance and colors can be easilygenerated. Furthermore, since the portion extracted from the image basedon the predetermined luminance and chroma extraction conditions movesfollowing movement of the image, changes of visual effects of an imagecaused by movement of the image can be prevented.

In the special effect image generation apparatus of the presentembodiment, the selection and setting of the type of image conversion inthe image conversion setting and processing means, the setting of theluminance extraction conditions and/or chroma extraction conditions, andthe setting and adjustment of a mask pattern generated by the maskpattern generation means can be freely and independently performed bythe operator in accordance with the special effect image desired. As aresult, the operator can accurately generate a special effect image ofthe desired high quality, and it becomes possible to suitably handlemovement of the image by an easy operation of adjustment of the maskpattern.

Further, the special effect image generation apparatus of the presentembodiment may be provided with a wave-filtering shaping means forfiltering and shaping the output signal of the extraction conditionsetting means so as to broaden the luminance and chroma extractionregion. Therefore, a high quality special effect image wherein boundarylines are smoothly set can be generated.

While the invention has been described with reference to specificembodiment chosen for purpose of illustration, it should be apparentthat numerous modification could be made thereto by those skilled in theart without departing from the basic concept and scope of the invention.

1. A special effect image generation apparatus for processing an imagesignal (B) to generate a special effect, comprising: extractioncondition setting means for setting luminance and/or chrominanceextraction conditions to be applied to the image signal to extractvarious portions thereof, said extraction conditions being selected byan operator; image conversion means for performing predetermined imageconversion of said image signal to form a conversion signal (A); keysignal output means for generating and outputting a key signal (K)according to the set extraction conditions; a transformation unit forprocessing said image signal for reduction and movement of a designatedportion in the image; and a mixing circuit for receiving said keysignal, said image signal, and said conversion image signal and forgenerating a converted image signal therefrom in accordance with thefollowing relationship:converted image signal=(A−B)·K+B.